KR20140003019U - Lifting lug load test device of offshore structure - Google Patents

Abstract

The present invention relates to a lifting lug rod test apparatus for an offshore structure, and more particularly, to a lifting lug rod test apparatus for an offshore structure capable of easily carrying out a safety load test on a lifting lug without any actual weight.
To this end, a lifting lug rod test device for an offshore structure for testing a safety load of a lifting lug fixed on a block of a module constituting an offshore structure, the lifting lug rod testing device comprising: A pair of support rods formed integrally with the pair of support rods to connect the lower ends of the support rods to each other, and a through hole facing the lifting lugs vertically and downwardly at the center, And a coupling piece having a coupling hole formed in a direction perpendicular to the axis of the lug.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a lifting lug load test apparatus for an offshore structure,

The present invention relates to a lifting lug rod test apparatus for an offshore structure, and more particularly, to a lubrication test apparatus for a lifting lug rod test apparatus for an offshore structure, in which a safety load on a lifting lug can be easily tested, To a lifting lug load test apparatus for a structure.

For example, LNG FPSO (Floating, Production, Storage and Offloading), Oil FPSO, LNG FSRU (Floating Storage and Regasification Unit), FPU (Floating Production Unit).

LNG FPSO is an offshore structure used to produce natural gas, store the natural gas directly in the sea and store it in the LNG storage tank, and transfer the LNG stored in the LNG storage tank to the LNG transport if necessary.

Oil FPSO is an offshore structure used to produce and store petroleum instead of natural gas and to transfer the oil stored in the storage tank to the oil tanker.

In addition, the LNG FSRU is an offshore structure that stores LNG unloaded from an LNG carrier in the offshore sea and stores it in an LNG storage tank, then vaporizes the LNG if necessary, and supplies it to a customer on land.

In particular, the Oil FPSO and LNG FPSO are installed in an oil storage tank or an LNG storage tank in the hull, and are equipped with various facilities necessary to treat crude oil or natural gas (for example, production and liquefaction of natural gas) A topside module is installed, each module having a weight of approximately several hundred to several thousand tons.

Meanwhile, the above-described offshore structure is divided into a plurality of spaces and dried in each block so as to fulfill each characteristic, and each block is composed of a residence, a tank room, a machine room, and the like.

At this time, a lug is provided on the upper part of the block constituting the machine room.

The lugs serve to lift the large machine parts during maintenance of large machine parts such as decelerator and motor installed in the machine room.

That is, the lug is intended to be connected to lifting means of the lifting device for lifting the large mechanical parts in order to lift the large mechanical parts installed in the machine room.

At this time, in order to install the lugs, the lifting load of the lugs must be considered. It is very important to consider the safety load for lifting large machine parts weighing tens of tons.

However, conventionally, there has been a problem that it is not easy to test the safety load of the lug in the process of installing the lug on the convex.

In other words, it was difficult to test the safety load of the lug because the lifting of the large machine parts can not be practiced before the large machine parts are installed inside the block in the process of installing the block lugs.

Therefore, conventionally, there has been a problem that it is difficult to increase the accuracy and reliability of the safety load of the lug by installing the lug through the experience of the skilled worker.

Korea Registration No. 10-1021959 Republic of Korea public number 20-2011-0003159

The object of the present invention is to provide a lifting lug load test apparatus for an offshore structure capable of easily testing a safety load on a lifting lug installed on a module constituting an offshore structure. .

In order to accomplish the above object, the present invention provides a lifting lug rod testing apparatus for a marine structure for testing a safety load of a lifting lug fixed on a block of a module constituting an offshore structure, A pair of supporting rods each having an engaging groove formed at an upper end thereof, a pair of supporting rods connected to a lower end of the supporting rods, and a through hole facing the lifting lug, And a coupling piece formed on the coupling body and having a coupling hole formed in a direction perpendicular to the through hole. The present invention also provides a lifting lug rod testing apparatus for an offshore structure.

At this time, one side of the coupling groove part is preferably cut to form a cutting groove.

Preferably, the through hole is disposed in the through hole and is coupled to the coupling hole of the coupling piece.

The lifting lug rod test apparatus of an offshore structure according to the present invention has the following effects.

First, in order to test the safety load on the lifting lug, a series of procedures for the safety load test of the lifting lug are simplified and the convenience of the operation is improved since the actual weight does not need to be provided.

That is, a series of test procedures can be simplified since the load generating means such as a hydraulic cylinder is coupled to the coupling groove, and then the load cell pushes the load of the lifting lug using the force that the hydraulic cylinder pushes the upper portion of the block .

Secondly, one side of the engaging groove portion is cut to form a cutting groove, thereby facilitating the attachment and detachment of the hydraulic cylinder to the engaging groove portion.

That is, the hydraulic cylinder can be easily attached and detached by engaging or disengaging the hydraulic cylinder through one side of the coupling groove portion not above the coupling groove portion, regardless of the gap between the coupling groove portion and the upper block upper portion.

1 is a perspective view showing a lifting lug rod testing apparatus for an offshore structure according to a preferred embodiment of the present invention;
FIG. 2 is a front view showing a state in which a lifting lug load testing apparatus for an offshore structure according to a preferred embodiment of the present invention is installed on a lifting lug
3 is a side view showing a state in which a hydraulic cylinder is installed in a lifting lug rod testing apparatus for an offshore structure according to a preferred embodiment of the present invention;

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to best describe its own design in the best way It should be construed as meaning and concept consistent with the technical idea of the invention.

Hereinafter, a lifting lug rod testing apparatus for an offshore structure according to a preferred embodiment of the present invention will be described with reference to FIGS. 1 to 3 attached hereto.

The lifting lug rod test equipment for offshore structures has the technical feature to easily test the safety load of the lifting lugs installed in the blocks of the modules making up the offshore structure.

The lifting lug rod testing device of an offshore structure comprises a support 100, a connecting body 200, and a connecting piece 300.

The support 100 is a portion where a load means for generating a load is installed for the safety load test on the lifting lug L and serves to transmit the force from the load means downward.

The supports 100 are provided as a pair with the lifting lugs L therebetween, preferably in the form of a cylinder.

At this time, an engagement groove 110 is formed at the upper end of the support 100.

The coupling groove portion 110 is a portion where a load means described later is disposed and extends upward from the upper end of the support base 100 to form a predetermined space.

That is, the force of the load means can be generated toward the surface of the block provided with the lifting lug L in a state where the load means is disposed in the space of the coupling groove portion 110.

At this time, the coupling groove 110 is formed in the shape of a partition wall around the upper end of the support 100, and one side thereof is preferably cut to form the cutout groove 111.

This is for the purpose of allowing the load means, which will be described later, to be easily coupled to the engagement groove portion 110.

That is, the lifting means L is coupled to the inside of the coupling groove 110 through one side of the coupling groove 110 rather than the upper side of the coupling groove 110, so that the lifting lug L, which is disposed above the coupling groove 110, There is no interference with the surface of the installed block.

Next, the connector 200 integrally connects the pair of supports 100, and is formed at the lower end of the support 100.

At this time, a through hole 210 penetrating in the upward and downward directions is formed in the center of the connector 200.

The through hole 210 is a portion where a load cell to be described later is disposed, and is opposed to the lifting lug L.

Next, the coupling piece 300 is a portion to which the load cell arranged in the through hole 210 is coupled, and is formed at the center of the lower end of the coupling body 200.

At this time, a coupling hole 310 is formed in the coupling piece 300 and a coupling hole 310 is formed in a direction perpendicular to the through hole 210.

In order to perform the safety load test on the lifting lug L, the load unit 400, the load cell 500 for checking the load, the connection ring 600, the hydraulic pressure supply unit (not shown) Is provided.

The load means 400 serves to generate a load on the lifting lug L and is preferably provided as a hydraulic cylinder.

That is, a load is generated in the lifting lug L by using the hydraulic pressure of the hydraulic cylinder 400.

The load cell 500 is a device for checking the load by the hydraulic cylinder 400 and is a measuring device for displaying the safe load of the lifting lug L numerically.

The connection ring 600 is connected between the load cell 500 and the lifting lug L so that a force for pulling the lifting lug L downward, that is, a load, is transmitted to the lifting lug L.

And, although not shown, the hydraulic pressure supply device is a device that provides hydraulic pressure to the hydraulic cylinder 400. [

Hereinafter, a process of testing a safety load on a lifting lug using a lifting lug rod testing apparatus for an offshore structure constructed as described above will be described.

So that the lifting lug (L) is fixed by hooking the connecting hook (600).

At this time, the upper portion of the connecting hook 600 is coupled to the lifting lug L, and the lower portion of the connecting hook 600 is downwardly suspended.

Next, after the load cell 500 is disposed in the through hole 210 of the connector 200, the lower end of the load cell 500 is coupled to the engaging piece 300 using a fixing bolt.

Thereafter, the upper end of the load cell 500 is coupled to the lower portion of the connecting ring 600.

Thus, the lifting lug (L) load test device of the offshore structure in which the load cell 500 is installed is suspended from the linking ring 600.

Next, the hydraulic cylinder 400 is engaged with the coupling groove 110 of the support base 100.

At this time, the gap between the upper end of the coupling groove 110 and the surface of the block provided with the lifting lug L may be lower than the height of the hydraulic cylinder 400, so that one side of the coupling groove 110 To the inside of the engaging groove 110 through the incision groove 111 formed in the engaging groove 110.

Accordingly, the hydraulic cylinder 400 can be easily coupled to the coupling groove 110, and the coupling between the hydraulic hose H and the coupling groove 110, which is installed at one side of the hydraulic cylinder 400, do.

Next, when the installation of the lifting lug rod testing device of the offshore structure is completed as described above, the hydraulic cylinder 400 is operated to draw out the piston.

At this time, the piston exerts a force to push the surface of the block in which the lifting lug L is installed, and the support 100 acts to push downward by the reaction of the hydraulic cylinder 400.

At this time, the connection link 600 connected to the lifting lug L also generates a load downward, and the load is checked by the load cell 500.

That is, through this series of processes, it is possible to check to what extent the lifting lug L can withstand the load.

For example, in order to test the safety load of the lifting lug L with respect to the speed reducer having a weight of 20 tons, the lifting lug L must be installed so as to withstand a load 20% The safety load of the lifting lug L is determined to be no problem if the lifting lug L is not defective even if the force of the lifting lug L is applied until the force of the lifting lug L reaches 24 tons.

Thereafter, when the series of test procedures is completed, the operation of the hydraulic cylinder 400 is stopped and the lifting lug rod test apparatus of the offshore structure is removed from the lifting lug L and moved to test another lifting lug.

As described so far, the lifting lug load test apparatus for an offshore structure according to the present invention has a technical feature that it is possible to easily test a safety load on a lifting lug even if no actual parts are to be used to use the lifting lug.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: Support base 110:
111: incision groove 200:
210: through hole 300:
310: engaging hole 400: load means (hydraulic cylinder)
500: load cell 600: connecting ring

Claims (3)

CLAIMS 1. A lifting lug rod test apparatus for an offshore structure for testing the safety load of a lifting lug fixed on a block of a module constituting an offshore structure,
A pair of support rods disposed with a lifting lug therebetween and having coupling grooves formed at upper ends thereof;
A connecting body formed by connecting the lower ends of the supporting rods to integrate the pair of supporting rods, and a through hole facing the lifting lugs is formed to penetrate upward and downward at the center thereof;
And a coupling piece formed on the coupling body and having a coupling hole formed in a direction perpendicular to the through hole. The method according to claim 1,
Wherein one side of the coupling groove is cut to form a cutting groove. 3. The method according to claim 1 or 2,
Wherein the load cell is disposed in the through hole and is coupled to the coupling hole of the coupling piece.

Images